Construction of an IS946-based composite transposon in Lactococcus lactis subsp. lactis

Quantitative analysis of group II intron expression and splicing in Lactococcus lactis

The group II intron Ll.ltrB is found within the ltrB relaxase gene of the conjugative element pRS01 in Lactococcus lactis. Precise splicing of the intron is essential for pRS01 transfer. The transcription regulation and in vivo splicing activity of Ll.ltrB have not been investigated thoroughly in L. lactis in the natural pRS01 context. We developed absolute quantitative real-time reverse transcription-PCR assays to quantify RNA levels of the 5' exon (ltrBE1) and the spliced relaxase (ltrB) and intron-encoded protein (ltrA) genes, as well as Ll.ltrB splicing activity under different physiological conditions. The mRNA levels for the ATP-binding protein OppD were assayed for comparison to the ltrB transcripts. The oppD mRNA ranged from 10- to 10,000-fold higher than ltrB region genes. ltrBE1 expression was growth-phase dependent. The mRNA level of ltrA was almost constant during all growth phases and in all media tested. Ll.ltrB in vivo splicing activity ranged from (6.5 +/- 2.1)% to (22.1 +/- 8.0)%. Acid challenge significantly decreased both ltrB region mRNA levels and intron splicing activity. The presence of recipient cells, different mating environments, and temperature stress had no significant effects on expression and splicing. Western blotting showed that the level of LtrB protein expressed from an intronless ltrB gene was much higher (about 20-fold) than the level of protein expressed from an intron-containing construct. Interestingly, LtrB protein showed a tendency to function in cis on its oriT target. The low level of ltrB transcript and relatively inefficient splicing of the intron may limit Ll.ltrB mobility and dissemination in nature.

Regulation of intron function: efficient splicing in vivo of a bacterial group II intron requires a functional promoter within the intron

Conjugative transfer of the Lactococcus lactis plasmid pRS01 requires splicing of a group II intron, Ll.ltrB, for accurate translation of the mRNA for the exon gene ltrB. The protein product of ltrB is a conjugative relaxase, essential for pRS01 transfer. Using a molecular technique for the identification of transcription initiation sites in bacteria, a functional promoter within Ll.ltrB was identified upstream from the gene for the intron-encoded protein (IEP) LtrA. LtrA is required for efficient splicing of Ll.ltrB in vivo. Mutation of the ltrA promoter dramatically reduced the steady-state level of ltrA mRNA, LtrA, intron splicing and conjugation in L. lactis. These effects could be relieved by expression in trans of the ltrA gene cloned under the control of an inducible promoter. These results suggest that the ltrA mRNAs are translated inefficiently. We hypothesize that this bacterial intron, in contrast to previously studied group II introns in eukaryotes, requires a promoter within the intron to regulate ltrA expression and to produce an adequate level of the protein in the cell for efficient splicing.

Sequence and analysis of the 60 kb conjugative, bacteriocin-producing plasmid pMRC01 from Lactococcus lactis DPC3147

The complete sequence of pMRC01, a large conjugative plasmid from Lactococcus lactis ssp. lactis DPC3147, has been determined. Using a shotgun sequencing approach, the 60,232 bp plasmid sequence was obtained by the assembly of 1056 underlying sequences (sevenfold average redundancy). Sixty-four open reading frames (ORFs) were identified. Analysis of the gene organization of pMRC01 suggests that the plasmid can be divided into three functional domains, with each approximately 20 kb region separated by insertion sequence (IS) elements. The three regions are (i) the conjugative transfer region, including a 16-gene Tra (transfer) operon; (ii) the bacteriocin production region, including an operon responsible for the synthesis of the novel bacteriocin lacticin 3147; and (iii) the phage resistance and plasmid replication region of the plasmid. The complete sequence of pMRC01 provides important information about these industrially relevant phenotypes and gives insight into the structure, function and evolution of large gram-positive conjugative plasmids in general. The completely sequenced pMRC01 plasmid should also provide a useful framework for the design of novel plasmids to be incorporated into starter strain improvement programmes for the dairy industry.

Characterization of a mosaic ISS1 element and evidence for the recent horizontal transfer of two different types of ISS1 between Streptococcus thermophilus and Lactococcus lactis

A 12-kb region of the Streptococcus thermophilus CNRZ368 chromosome was found to contain two copies of IS981 (one complete and one truncated) and three copies of ISS1 (two complete, ISS1SA and ISS1SC, and one truncated, delta ISS1SB). Comparison of the nucleotide sequences of these ISS1 elements with those of previously identified iso-ISS1 elements from Lactococcus lactis and the Enterococcus genus indicated that the ISS1 group is divided into three distinct subgroups which we have named alpha, beta and gamma. Nucleotide sequences of elements belonging to the same subgroup share more than 97% identity whereas sequences of elements from different groups share only 75-85% identity. Sequence analysis of ISS1SA and delta ISS1SB showed that they are members of the alpha group. We found that ISS1SC from S. themophilus CNRZ368, an ISS1 from L. lactis IL964 and IS946 from L. lactis TEK1 resulted from recombinations between alpha and beta elements. In addition, ISS1W from L. lactis Wg2 resulted from a recombination event between a gamma element and an ISS1 belonging to an unidentified subgroup. ISS1 sequences belonging to the alpha and beta subgroups were found in both S. thermophilus and L. lactis and gamma sequences were found in both the Enterococcus genus and L. lactis. The quasi-identity of some ISS1 elements in S. thermophilus and L. lactis and the distribution of alpha and beta elements suggest that horizontal transfer of ISS1 elements recently took place from L. lactis to S. thermophilus, two lactic acid bacteria used in the manufacture of cheeses. Since the presence of IS981 in S. thermophilus CNRZ368 also probably resulted from a horizontal transfer from L. lactis [Guédon et al. (1995) Mol. Microbiol. 16, 69-78], the 12-kb region bearing IS981 and ISS1 elements could be due to the integration of a lactococcal DNA fragment into the chromosome.

Bacteriophage resistance in Lactococcus

Lactic acid bacteria are industrial microorganisms used in many food fermentations. Lactococcus species are susceptible to bacteriophage infections that may result in slowed or failed fermentations. A substantial amount of research has focused on characterizing natural mechanisms by which bacterial cells defend themselves against phage. Numerous natural phage defense mechanisms have been identified and studied, and recent efforts have improved phage resistance by using molecular techniques. The study of how phages overcome these resistance mechanisms is also an important objective. New strategies to minimize the presence, virulence, and evolution of phage are being developed and are likely to be applied industrially.

In vivo restriction by LlaI is encoded by three genes, arranged in an operon with llaIM, on the conjugative Lactococcus plasmid pTR2030

The LlaI restriction and modification (R/M) system is encoded on pTR2030, a 46.2-kb conjugative plasmid from Lactococcus lactis. The llaI methylase gene, sequenced previously, encodes a functional type IIS methylase and is located approximately 5 kb upstream from the abiA gene, encoding abortive phage resistance. In this study, the sequence of the region between llaIM and abiA was determined and revealed four consecutive open reading frames (ORFs). Northern (RNA) analysis showed that the four ORFs were part of a 7-kb operon with llaIM and the downstream abiA gene on a separate transcriptional unit. The deduced protein sequence of ORF2 revealed a P-loop consensus motif for ATP/GTP-binding sites and a three-part consensus motif for GTP-binding proteins. Data bank searches with the deduced protein sequences for all four ORFs revealed no homology except for ORF2 with MerB, in three regions that coincided with the GTP-binding motifs in both proteins. To phenotypically analyze the llaI operon, a 9.0-kb fragment was cloned into a high-copy-number lactococcal shuttle vector, pTRKH2. The resulting construct, pTRK370, exhibited a significantly higher level of in vivo restriction and modification in L. lactis NCK203 than the low-copy-number parental plasmid, pTR2030. A combination of deletion constructions and frameshift mutations indicated that the first three ORFs were involved in LlaI restriction, and they were therefore designated llaI.1, llaI.2, and llaI.3. Mutating llaI.1 completely abolished restriction, while disrupting llaI.2 or llaI.3 allowed an inefficient restriction of phage DNA to occur, manifested primarily by a variable plaque phenotype. ORF4 had no discernible effect on in vivo restriction. A frameshift mutation in llaIM proved lethal to L. lactis NCK203, implying that the restriction component was active without the modification subunit. These results suggested that the LlaI R/M system is unlike any other R/M system studied to date and has diverged from the type IIS class of restriction enzymes by acquiring some characteristics reminiscent of type I enzymes.

Genetic analysis of regions of the Lactococcus lactis subsp. lactis plasmid pRS01 involved in conjugative transfer

The genes responsible for conjugative transfer of the 48.4-kb Lactococcus lactis subsp. lactis ML3 plasmid pRS01 were localized by insertional mutagenesis. Integration of the IS946-containing plasmid pTRK28 into pRS01 generated a pool of stable cointegrates, including a number of plasmids altered in conjugative proficiency. Mapping of pTRK28 insertions and phenotypic analysis of cointegrate plasmids identified four distinct regions (Tra1, Tra2, Tra3, and Tra4) involved in pRS01 conjugative transfer. Tra3 corresponds closely to a region previously identified (D. G. Anderson and L. L. McKay, J. Bacteriol. 158:954-962, 1984). Another region (Tra4) was localized within an inversion sequence shown to correlate with a cell aggregation phenotype. Tra1 and Tra2, two previously unidentified regions, were located at a distance of 9 kb from Tra3. When provided in trans, a cloned portion of the Tra3 region complemented Tra3 mutants.

Transposable elements in Lactococci: a review

Genetic studies have identified the presence of transposable elements within the genus Lactococcus, which includes industrially important microorganisms used in the production of fermented dairy products. Three insertion sequences have been fully characterized in addition to several reports of transpositionlike events. The three insertion sequence elements, ISS1, IS904, and IS981, exhibit the physical and genetic properties characteristic of known insertion sequences. They are closely related to insertion sequences isolated from a wide variety of microorganisms. In lactococci, insertion sequence elements are associated with lactose and sucrose metabolism, proteinase activity, nisin production and immunity, conjugal transfer determinants, and bacteriophage resistance, which are attributes significant for growth in a milk environment. The characteristics, involvement in lactococcal evolution, and recent developments as tools for genetic engineering of the lactococcal elements are discussed.